The Effect of Doping rGO with Nanosized MnO[sub.2] on Its Gas Sensing Properties

Manganese dioxide (MnO[sub.2] ) has drawn attention as a sensitiser to be incorporated in graphene-based chemoresistive sensors thanks to its promising properties. In this regard, a rGO@MnO[sub.2] sensing material was prepared and deposited on two different substrates (silicon and Kapton). The effec...

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Veröffentlicht in:	Chemosensors 2024-12, Vol.12 (12)
Hauptverfasser:	Alouani, Mohamed Ayoub, Casanova-Chafer, Juan, de Bernardi-Martín, Santiago, García-Gómez, Alejandra, Salehnia, Foad, Santos-Ceballos, José Carlos, Santos-Betancourt, Alejandro, Vilanova, Xavier, Llobet, Eduard
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Schlagworte:	Ammonia Design and construction Graphene Graphite Materials Metallic oxides Sensors Silicon
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creator	Alouani, Mohamed Ayoub Casanova-Chafer, Juan de Bernardi-Martín, Santiago García-Gómez, Alejandra Salehnia, Foad Santos-Ceballos, José Carlos Santos-Betancourt, Alejandro Vilanova, Xavier Llobet, Eduard
description	Manganese dioxide (MnO[sub.2] ) has drawn attention as a sensitiser to be incorporated in graphene-based chemoresistive sensors thanks to its promising properties. In this regard, a rGO@MnO[sub.2] sensing material was prepared and deposited on two different substrates (silicon and Kapton). The effect of the substrate nature on the morphology and sensing behaviour of the rGO@MnO[sub.2] material was thoroughly analysed and reported. These sensors were exposed to different dilutions of NO[sub.2] ranging from 200 ppb to 1000 ppb under dry and humid conditions (25% RH and 70% RH) at room temperature. rGO@MnO[sub.2] deposited on Kapton showed the highest response of 6.6% towards 1 ppm of NO[sub.2] under dry conditions at RT. Other gases or vapours such as NH[sub.3] , CO, ethanol, H[sub.2] and benzene were also tested. FESEM, HRTEM, Raman, XRD and ATR-IR were used to characterise the prepared sensors. The experimental results showed that the incorporation of nanosized MnO[sub.2] in the rGO material enhanced its response towards NO[sub.2] . Moreover, this material also showed very good responses toward NH[sub.3] both under dry and humid conditions, with the rGO@MnO[sub.2] sensor on silicon showing the highest response of 18.5% towards 50 ppm of NH[sub.3] under 50% RH at RT. Finally, the synthetised layers showed no cross-responsiveness towards other toxic gases.
doi_str_mv	10.3390/chemosensors12120256
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In this regard, a rGO@MnO[sub.2] sensing material was prepared and deposited on two different substrates (silicon and Kapton). The effect of the substrate nature on the morphology and sensing behaviour of the rGO@MnO[sub.2] material was thoroughly analysed and reported. These sensors were exposed to different dilutions of NO[sub.2] ranging from 200 ppb to 1000 ppb under dry and humid conditions (25% RH and 70% RH) at room temperature. rGO@MnO[sub.2] deposited on Kapton showed the highest response of 6.6% towards 1 ppm of NO[sub.2] under dry conditions at RT. Other gases or vapours such as NH[sub.3] , CO, ethanol, H[sub.2] and benzene were also tested. FESEM, HRTEM, Raman, XRD and ATR-IR were used to characterise the prepared sensors. The experimental results showed that the incorporation of nanosized MnO[sub.2] in the rGO material enhanced its response towards NO[sub.2] . Moreover, this material also showed very good responses toward NH[sub.3] both under dry and humid conditions, with the rGO@MnO[sub.2] sensor on silicon showing the highest response of 18.5% towards 50 ppm of NH[sub.3] under 50% RH at RT. 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In this regard, a rGO@MnO[sub.2] sensing material was prepared and deposited on two different substrates (silicon and Kapton). The effect of the substrate nature on the morphology and sensing behaviour of the rGO@MnO[sub.2] material was thoroughly analysed and reported. These sensors were exposed to different dilutions of NO[sub.2] ranging from 200 ppb to 1000 ppb under dry and humid conditions (25% RH and 70% RH) at room temperature. rGO@MnO[sub.2] deposited on Kapton showed the highest response of 6.6% towards 1 ppm of NO[sub.2] under dry conditions at RT. Other gases or vapours such as NH[sub.3] , CO, ethanol, H[sub.2] and benzene were also tested. FESEM, HRTEM, Raman, XRD and ATR-IR were used to characterise the prepared sensors. The experimental results showed that the incorporation of nanosized MnO[sub.2] in the rGO material enhanced its response towards NO[sub.2] . Moreover, this material also showed very good responses toward NH[sub.3] both under dry and humid conditions, with the rGO@MnO[sub.2] sensor on silicon showing the highest response of 18.5% towards 50 ppm of NH[sub.3] under 50% RH at RT. 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In this regard, a rGO@MnO[sub.2] sensing material was prepared and deposited on two different substrates (silicon and Kapton). The effect of the substrate nature on the morphology and sensing behaviour of the rGO@MnO[sub.2] material was thoroughly analysed and reported. These sensors were exposed to different dilutions of NO[sub.2] ranging from 200 ppb to 1000 ppb under dry and humid conditions (25% RH and 70% RH) at room temperature. rGO@MnO[sub.2] deposited on Kapton showed the highest response of 6.6% towards 1 ppm of NO[sub.2] under dry conditions at RT. Other gases or vapours such as NH[sub.3] , CO, ethanol, H[sub.2] and benzene were also tested. FESEM, HRTEM, Raman, XRD and ATR-IR were used to characterise the prepared sensors. The experimental results showed that the incorporation of nanosized MnO[sub.2] in the rGO material enhanced its response towards NO[sub.2] . Moreover, this material also showed very good responses toward NH[sub.3] both under dry and humid conditions, with the rGO@MnO[sub.2] sensor on silicon showing the highest response of 18.5% towards 50 ppm of NH[sub.3] under 50% RH at RT. Finally, the synthetised layers showed no cross-responsiveness towards other toxic gases.</abstract><pub>MDPI AG</pub><doi>10.3390/chemosensors12120256</doi></addata></record>
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subjects	Ammonia Design and construction Graphene Graphite Materials Metallic oxides Sensors Silicon
title	The Effect of Doping rGO with Nanosized MnO[sub.2] on Its Gas Sensing Properties
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